Ataxia-telangiectasia


ARTICLE OPEN ACCESS

Ataxia-telangiectasia
A new remitting form with a peculiar transcriptome signature

Vincenzo Leuzzi, MD, Daniela D’Agnano, MD, Michele Menotta, PhD, Caterina Caputi, MD, Luciana Chessa, MD,

and Mauro Magnani, PhD

Neurol Genet 2018;4:e228. doi:10.1212/NXG.0000000000000228

Correspondence

Dr. Leuzzi

vincenzo.leuzzi@uniroma1.it

Abstract
Objective
Ataxia-telangiectasia (AT) is a rare, severe, and ineluctably progressive multisystemic neuro-
degenerative disease. Variant AT phenotypes have been described in patients with mild- and
late-onset neurologic deterioration and atypical features (dystonia and myoclonus). We report
on the clinical characteristics and transcriptome profile of patients with a typical AT pre-
sentation and genotype who experienced an unexpected favorable course.

Methods
A 24-year-old woman developed, by the age of 3 years, all the classic symptoms of AT associated
with increased alpha-fetoprotein levels, a compound AT-mutated (ATM) genotype with an
inframe deletion c.2250G>A (p.Glu709_Lys750del42) and a missense mutation c.8122G>A
(p.Asp2708Gln), and no residual ATM protein expression. By the age of 12 years, ataxia slowly
disappeared, and a very mild choreic disorder was the only neurologic feature in adulthood.
Brain MRI was normal. The blood transcriptome profile was assessed and compared with that
of healthy controls and patients with the classic AT phenotype.

Results
The atypical clinical course of the patient was associated with a transitional transcriptome
profile: while 90% of transcripts were expressed as in patients with the classic AT presentation,
10% of transcripts were expressed as in healthy controls.

Conclusions
The unexpected mild clinical outcome and transcriptome profile of this patient with AT suggest
the existence of individual resilience to the altered ATM synthesis. Because of their possible
prognostic and therapeutic implications, the identification of modifier factors affecting the
phenotype would deserve further studies.

From the Department of Pediatrics, Child Neurology and Psychiatry (V.L., D.D.A., C.C.), and Faculty of Medicine and Psychology (L.C.), Sapienza University of Rome “La Sapienza”; and
Department of Biomolecular Sciences (M. Menotta, M. Magnani), University of Urbino “Carlo Bo,” Italy.

Funding information and disclosures are provided at the end of the article. Full disclosure form information provided by the authors is available with the full text of this article at
Neurology.org/NG.

The Article Processing Charge was funded by the authors.

This is an open access article distributed under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives License 4.0 (CC BY-NC-ND), which permits downloading
and sharing the work provided it is properly cited. The work cannot be changed in any way or used commercially without permission from the journal.

Copyright © 2018 The Author(s). Published by Wolters Kluwer Health, Inc. on behalf of the American Academy of Neurology. 1

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Ataxia-telangiectasia (AT; OMIM#208900) is a rare genetic
disease caused by mutations in the AT-mutated (ATM) gene
encoding PI3kinase, which controls the cell cycle and DNA
repair.1 Patients with classic AT present with early-onset
progressive cerebellar ataxia, oculocutaneous telangiectasias,
immunodeficiency, late-onset peripheral neuropathy, and
higher incidence of infections and tumors. Patients usually use
a wheelchair by the age of 10 years. Exitus occurs by the
second or third decade of life because of chronic lung disease
or malignancies. Biomarkers of the disease are increased
alpha-fetoprotein (AFP) (95% of patients),2 chromosomal
radiosensivity, and undetectable ATM protein (98% of
patients). Milder variants (late-onset, slowly progressive
ataxia/dyskinesia syndrome) have been associated not only
with missense ATM mutations and residual ATM kinase ac-
tivity3 but also with the classic severe genotype and absent
ATM protein.4

Here, we report on a new clinical variant with an early pro-
gressive course, late remission, and stable neurologic status
until adulthood, despite the classic ATM genotype and absent
ATM protein. Accordingly, blood transcriptome in this case
showed a pattern of alteration intermediate between healthy
controls and severely affected patients.

Case report
A 24-year-old woman was born after a normal pregnancy and
delivery from healthy unrelated parents. Psychomotor de-
velopment was normal until the age of 16 months when trunk
swaying was noticed by the parents. On examination, she was
found to have mild trunk ataxia, external beating nystagmus, mild
conjunctival angioectasias, and subcutaneous angiomas in the
lumbar and calf regions. Brain MRI and sensory and motor nerve
conduction velocities were normal. Blood immunoglobulin A
(IgA) levels were marginally decreased (78 mg/100 mL; r.v.
85–450), whereas the AFP level was increased (37.5 ng/mL; r.v.
0–10). Chromosome analysis revealed a 7;14 rearrangement,
and the radiosensitivity test demonstrated increased chromo-
some instability. No residual ATM protein expression or activity
was found. Molecular analysis of the ATM gene disclosed
a compound heterozygous genotype with an inframe deletion
c.2250G>A, p.(Glu709_Lys750del42) and a missense mutation
c.8122G>A, p.(Asp2708Gln).

In the following years, trunk ataxia worsened and other neu-
rologic features, such as motor impersistence and chorea of
the trunk and limbs, slurred speech, and hypometric saccades,
emerged. Nevertheless, the ability to walk autonomously was
preserved, and she could attend a normal school and conduct
a normal life. Mental development was normal: at the age of 7
years, the Wechsler Intelligence Scale for Children-Revised
IQ score was 92. Starting from the age of 12 years, trunk ataxia

progressively disappeared. On examination, at the age of 24
years, she presented with only mild clumsiness associated with
nondisabling choreic movements of the limbs (video, links.
lww.com/NXG/A47). The International Cooperative Ataxia
Rating Scale score was 2 (normal 0). Brain MRI was normal.
She maintained normal mental functioning (Wechsler Adult
Intelligence Scale IQ score 110, Verbal IQ score 104, and
performance IQ score 79) with adequate personal and social
skills. She never had pulmonary infections; MRI of the lung
performed at the age of 21 years was normal. Her menses were
irregular, and she had polycystic ovarian syndrome. She un-
derwent surgical removal of ameloblastoma of the mandible.
Recently, ultrasonography has revealed a fatty liver disease in
the absence of dyslipidemia or abnormal liver enzymes. At the
age of 22 and 24 years, the AFP level was 115 and 190 ng/mL,
respectively; the serum IgA level was normal.

Transcriptome analysis: the study of a whole gene expression
signature (appendix e-1, links.lww.com/NXG/A46) showed
that 1,326 probes were differentially expressed (upregulated
and downregulated, table e-1, links.lww.com/NXG/A43) in 5
patients with classic AT compared with healthy controls.5

Using these probes in hierarchical clustering computation
(figure 1), our case resulted as a nonclustered sample: 90% of
probes were expressed as in patients with classic AT (cutoff
1.2 FC), whereas 10% of them were expressed as in healthy
controls. Of 654 gene symbols derived from the differently
expressed probes, 43 gene transcripts had an expression level
similar to the healthy controls (table e-2, links.lww.com/
NXG/A44). Two of them, such as ZCRB1 (a zinc finger RNA
binding protein) and THOC3 (a protein involved in splicing)
showed a biological and molecular functional interaction
when analyzed by Reactome FI [1] (plugin for Cytoscape).6

Patient consent
The patient provided informed consent for participating in
the research and publishing the resulting data. She also pro-
vided consent to disclose of any recognizable person in the
video.

Discussion
We describe an unusual AT phenotype, characterized by
a clinical presentation mimicking the classic severe form with
the typical biomarkers of this condition, such as absent ATM
protein,7 14 chromosome rearrangement, and increasing
levels of AFP, with an unexpected favorable course of neu-
rologic disorders during teenage years.

The ATM protein level and residual kinase activity seem to
influence the severity of the clinical phenotype in patients
with AT. Variant AT has been documented in patients

Glossary
AFP = alpha-fetoprotein; AT = ataxia-telangiectasia; ATM = ataxia-telangiectasia mutated; IgA = immunoglobulin A.

2 Neurology: Genetics | Volume 4, Number 2 | April 2018 Neurology.org/NG

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http://links.lww.com/NXG/A46
http://links.lww.com/NXG/A43
http://links.lww.com/NXG/A44
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presenting with a mild neurologic phenotype, often normal
brain MRI, and less frequent extraneurologic involvement. In
these cases, regulatory, missense, or leaky splicing ATM
mutations and a residual ATM activity were detected.4 The
genotype of our patient is characterized by an inframe de-
letion and a missense mutation without residual ATM activity.
Accordingly, a classic presentation and outcome should have
been expected. Recent reports showed that absent ATM ac-
tivity and high AFP may be associated with a late-onset or
atypical neurologic presentation (table e-3, links.lww.com/
NXG/A45). Of interest, 3 patients belonging to the Canadian

Mennonites with late dystonia/myoclonus-dystonia syn-
drome associated with 6200C>A mutation had transient
ataxia in early childhood. The same genotype has been
reported in a patient with early-onset myoclonus-dystonia,
high blood AFP, and progressive cerebellar atrophy.4

In contrast to these cases, our patient experienced the classic
presentation and course of the disease until the end of the first
decade of life when progressively ataxia vanished, leaving a mild
and stable choreic disorder. Nevertheless, AFP and some sys-
temic manifestations of AT (such as ovarian polycystic

Figure 1 Hierarchical clustering (HCL) outcome of all tested samples with the expression profile of the case report set as
unknown

Only a partial gene list is reported (the whole HCL
figure is available as figure e-1, links.lww.com/NXG/
A42). The probes resulting statistically different
between AT and WT groups (permutation-based t
test, p ≤ 0.01) allowed to cluster the atypical patient
out of the dendrogram. The colors (green, down-
regulated; red, upregulated) denote the expression
level of each used probe. The probe names and the
matching gene names are reported on the left and
on the right of the Y axis, respectively.

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syndrome, liver steatosis, and neoplasm) occurred. The as-
sumption that the AFP level may mirror the progression of the
disease remains debated.8 In our patient, the AFP level in-
creased, despite the improvement in neurologic disorder.

The atypical favorable outcome reported in our patient sug-
gests the possible effect of epigenetic modifying factors, which
may confer resilience to the disease in some subjects. One
modifying factor of the effect of ATM loss has been identified
in the Rad50s allele of the gene encoding the Rad50 com-
ponent of the Mre11/Rad50/Nbs1 complex. In the murine
model, Rad50s has a role in alleviating senescence, radiosen-
sitivity, and tumor formation, all hallmarks of ATM-deficient
mice.9 Moreover, recent data suggested a pivotal role of the
Rad50 hook domain in influencing the Mre11 complex-
dependent DNA damage response. In our patient, peripheral
Rad50 expression overlaps that detected in patients with AT
with a typical phenotype. A further hypothesis concerns the
variability in the maintaining of the cellular balance of reactive
oxygen species, which cause, among the others, defects in
hematopoietic stem cells10 and neurodegeneration.

In a recent article, we identified the transcriptome profile of
patients with AT with respect to healthy controls.5 The
present case exhibited transitional probe expression from that
found in patients with classic AT and healthy controls.
However interesting, this result requires caution because only
known probes were screened while we were unable to de-
termine whether unknown and unpredicted contributing
events, such as splicing pattern alteration, could take place. In
any case, the observed gene expression variation was part of
the final outcome of the patient’s biological individuality.

The 2 most important genes expressed were scrb1 and thoc3,
which are involved in wound reparation and genome stability,
respectively. Thoc3 is part of the THO complex, which plays
a role in transcriptional elongations, nuclear RNA export, and
genome stability.

The finding of a transitional transcriptome profile suggests the
occurrence of modifying factors possibly influencing individual
vulnerability and resilience to the altered ATM synthesis
resulting in an unexpected mild outcome.

Author contributions
Vincenzo Leuzzi and Daniela D’Agnano: drafting/revising the
manuscript, analysis and interpretation of clinical and

biochemical data, and acquisition of data. Michele Menotta:
drafting/revising the manuscript, analysis and interpretation
of biochemical data, and acquisition of data. Caterina Caputi:
drafting/revising the manuscript, analysis and interpretation
of clinical and biochemical data, and acquisition of data.
Luciana Chessa: drafting/revising the manuscript, analysis
and interpretation of clinical and biochemical data, and
molecular analysis interpretation. Mauro Magnani: drafting/
revising the manuscript, analysis and interpretation of clinical
and biochemical data, and acquisition of data.

Study funding
No targeted funding reported.

Disclosure
V. Leuzzi, D. D’Agnano, M. Menotta, C. Caputi, and
L. Chessa report no disclosures. M. Magnani has served on the
scientific advisory board of, holds stock/stock options in,
and/or receives board of directors’ compensation from
EryDel SpA; holds a patent regarding a method for the en-
capsulation of agents within erythrocytes; and has received
research support from EryDel SpA and Fondazione Cassa di
Risparmio di Fano. Full disclosure form information provided
by the authors is available with the full text of this article at
Neurology.org/NG.

Received September 17, 2017. Accepted in final form November 29,
2017.

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4 Neurology: Genetics | Volume 4, Number 2 | April 2018 Neurology.org/NG

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DOI 10.1212/NXG.0000000000000228
2018;4; Neurol Genet 

Vincenzo Leuzzi, Daniela D'Agnano, Michele Menotta, et al. 
Ataxia-telangiectasia: A new remitting form with a peculiar transcriptome signature

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